Hydrogen generation process with dual pressure multi stage electrolysis

ABSTRACT

A multi-pressure hybrid sulfur process ( 2 ) contains at least one electrolyzer unit ( 16 ) which provides liquid H 2 SO 4  to a preheater/vaporizer reactor ( 20 ) operating at a pressure of from 1 MPa to 9 MPa to form gaseous H 2 SO 4  which is passed to a decomposition reactor ( 14 ) operating at a pressure of from 7 MPa to 9 MPa, where decomposed H 2 SO 4  is passed to at least one scrubber unit ( 14 ) and at least one electrolyzer unit ( 16 ) both preferably operating at a pressure of 0.1 MPa to 7 MPa, where an associated Rankine Cycle power conversion unit ( 50 ) supplies electricity.

CROSS-REFERENCE TO RELATED APPLICATIONS

The instant application claims priority from Provisional Application No. 60/831,332 filed on Jul. 17, 2006.

BACKGROUND OF THE INVENTION

The sulfur cycles are a group of thermochemical processes that can make hydrogen, mainly using high temperature thermal energy from a high temperature heat source. The Westinghouse Sulfur Process (WSP; also known as the HyS or Hybrid Sulfur Process), FIG. 1 and the Sulfur Iodine (S/I) Process, FIG. 2 are two processes in this category. The high temperature heat sources are any that produce heat, available for use, above about 800° C., such as a High-Temperature Gas-Cooled Nuclear Reactor (HTGR) or a natural gas fired combustor.

The Westinghouse Sulfur Process produces hydrogen in a low-temperature electrochemical step, in which sulfuric acid and hydrogen are produced from sulfurous acid. This reaction can be run at between 0.17 and 0.6 volts with a current density of about 500 ma/sq.cm at about 60° C. The second step in the cycle is the high temperature decomposition of sulfuric acid at 760° C. or above. Previous work by Westinghouse has identified catalysts and process designs to carry out this reaction in concert with an HTGR such as the PBMR. The final step in this process is absorption of the SO₂ in water at room temperature to form sulfurous acid and a SO₂ free stream of O₂. This is a well known process which is hereby defined as “standard WSP”: H₂SO₄⇄SO₃+H₂O⇄SO₂+O.5O₂+H₂O (>760° C. heat required);   (1) SO₂+2H₂O+0.5O₂⇄H₂SO₃+H₂O+O.5O₂ (T<100° C.); and  (2) H₂O+H₂SO₃→H₂+H₂SO₄ (electrolyzer at about 100° C. or less).  (3)

The Iodine/Sulfur Process also starts with a reversible reaction where sulfuric acid is decomposed at over 760° C. to form sulfur dioxide as above, followed by the reaction of the sulfur dioxide with Iodine to form HI. This is a well known process which is hereby defined as “standard S/I”: H₂SO₄⇄SO₃+H₂O⇄SO₂+O.5O₂+H₂O (>760° C. heat required);   (1) I₂+SO₂+2H₂O+O.5O₂+excess H₂O⇄2HI+H₂SO₄+O.5O₂+excess H₂O (about 100° C. to 200° C. heat generated); and  (2) 2HI⇄H₂+I₂ (greater than 400° C. heat required).  (3)

The common step in both processes is: H₂SO₄⇄SO₂+H₂O+0.50₂

These standard WSP and standard S/I processes are described in detail by Lahoda et al. in U.S. Publication No. US 2006/0002845 A1.

Goosen et al.“Improvements in the Westinghouse Process for Hydrogen Production” American Nuclear Society Global Paper #88017, American Nuclear Society Annual Winter Meeting New Orleans, Louisiana, USA, November 2003, also describes the Westinghouse Sulfur Process and compares it with the Sulfur Iodine Process. Westinghouse process economics are described as well as integration with a nuclear High Temperature Gas Cooled Reactor (HTGR) such as a Pebble Bed Modular Reactor (PBMR) to drive reactions by delivering temperatures of about 800° C.-900° C. to H₂SO₄ reactors in the WSP or S/I Processes.

After the H₂SO₄ Decomposition Reactor (a process step common to both the standard WPS and S/I processes), the hot gas from the primary loop of a HTGR is sent to a Power Conversion Unit (PCU), consisting of a set of gas turbines where the remaining energy is extracted. Unfortunately, after extraction of the high quality heat needed for H₂SO₄ decomposition, the temperature of the gas is no longer high enough to take full advantage of the high efficiencies available from preferred Brayton cycle gas turbines.

The portion of the process where sulfuric acid is decomposed into sulfur dioxide, water vapor and oxygen, 12 in FIG. 1, typically takes place at high temperatures. Due to the lower condensation temperature of the Decomposition Reactor product stream compared to the feed stream, the SO₂/H₂O/O₂ outlet of the preheater/vaporization unit, 20 in FIG. 1, must be kept at a relatively high temperature, typically approximately 260° C. at 9 MPa. (1 MPa=145 pounds/sq. in “psi”). As a result, the amount of heat that can be recovered in the preheater is limited. The SO₂/O₂/H₂O stream must eventually be cooled to approximately 90° C. before being introduced to SO₂ scrubbers, shown generally as 14 in FIG. 1, so that this cooling duty represents a significant loss of energy.

The preheating/vaporization unit, 20 in FIG. 1 presents a severe materials issue as well. As it is evaporated, water is boiled off first, so that this stream changes in the Preheater from a relatively dilute H₂SO₄ solution of around 30% to 50% by weight, to a concentrated solution of 80% to 95% by weight H₂SO₄ when the highest temperatures are reached. While there are materials that can operate at the required temperatures (200° to 700° C.), they are very expensive.

Another inefficiency that is built into the process is evaporation and condensation of water that enters with the feed H₂SO₄. The sulfuric acid feed is typically 30% to 50% weight, so that a large amount of water is preheated and evaporated, only to be condensed and recirculated. The heat of vaporization of this water represents another substantial energy penalty. The decomposition process is typically aided by the presence of catalysts, and any water in the feed to the decomposition process can significantly reduce the decomposition catalyst life.

After cooling, the SO₂/O₂/H₂O stream is sent to the SO₂ scrubber and O₂ recovery until, generally shown as 14 in FIG. 1, where SO₂ is absorbed into water to make sulfurous acid (H₂O+SO₂⇄H₂SO₃). This sulfurous acid is then fed to an aqueous phase electrolysis cell, 16 in FIG. 1, where the sulfurous acid is oxidized to sulfuric acid, generating hydrogen product (2H₂O+SO₂⇄H₂+H₂SO₄). In order for the electrolysis step to work efficiently, the SO₂ must remain dissolved in the water. Sulfur dioxide has a limited aqueous solubility. Increasing the pressure increases the amount of SO₂ that can be absorbed into the scrubber solution, decreases the level of SO₂ in the O₂ product, and decreases the amount of makeup SO₂ that must be provided. However, increasing pressure also increases the cost of the process equipment, especially the vessels that contain the electrolysis units.

Thus, there continually remains a need to reduce operating temperatures and pressures so that low cost steels can be used and to increase efficiencies. It is a main object of this invention to provide a system using low temperatures, low pressures and high efficiencies.

SUMMARY OF THE INVENTION

Accordingly the above needs are met and object achieved by providing a hybrid sulfur process that utilizes a dual pressure system comprising a H₂SO₄ vaporization unit, a H₂SO₄ disassociation decomposition reactor operating at a pressure of from 7 MPa to 9 MPa, a product cooler and an SO₂ recovery process that also generates O₂, operating at a pressure of 0.1 MPa to 7 MPa feeding to an electrolyzer producing H₂ at same pressure.

This invention also resides in a hybrid sulfur process which comprises (a) a sulfur cycle, selected from the group consisting of a Westinghouse Sulfur Process and a Sulfur Iodine Process, comprising an electrolyzer which provides H₂SO₄ liquid to a H₂SO₄ vaporizer reactor operating at a pressure of from 1 MPa to 9 MPa and a temperature effective to provide vaporized gaseous H₂SO₄ which is decomposed to gaseous H₂O, SO₂ and O₂ in a decomposition reactor operating at a pressure of from 7 MPa to 9 Mpa, which gases are passed to at least one SO₂ scrubber unit(s) operated with at least one electrolyzer unit, where input electricity to the electrolyzer unit(s) result in the production of hydrogen gas and H₂SO₄ liquid, where both the SO₂ scrubber unit(s) and the electrolyzer units operate at a pressure of 0.1 MPa to 7 MPa; (b) Rankine Cycle Power Conversion Unit, which supplies electricity to at least the electrolyzer unit(s); and (c) a heat source selected from the group consisting of a nuclear reactor and a gas fired combustor, which supplies fluid heat to the Rankine Cycle Unit and the sulfur cycle.

BRIEF DESCRIPTION OF THE DRAWINGS

For a better understanding of the invention, reference may be made to the following description, taken in connection with the accompanying drawings in which:

FIG. 1 is a prior art block diagram of a Westinghouse Sulfur Process;

FIG. 2 is a prior art block diagram of a Sulfur Iodine Process;

FIG. 3, which best describes the invention is one example of an integrated flow diagram of a hybrid sulfur process using a Rankine Cycle and hydrogen production;

FIG. 4 illustrates the operation of an actual Rankine cycle;

FIG. 5 is a block diagram illustrating the interconnection of PCU and Hybrid Sulfur Systems to minimize thermal energy losses;

FIG. 6 is a block diagram illustrating a multistage SO₂ absorber electrolysis system in parallel; and

FIG. 7 is an integrated H₂SO₄ concentrator and H₂S decomposition reactors.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Back now to prior art FIGS. 1 and 2 before proceeding further with the invention. FIG. 1, illustrates a standard WSP process 2 shown operating at less than 900 psi. In FIG. 2, the standard S/I process 4 is shown operating at less than 900 psi. In FIG. 1, thermal energy 10 at about 760° C. to 1000° C. is passed into oxygen generator/sulfuric acid Decomposition Reactor 12 to provide the reaction shown, passing H₂O, SO₂ and O₂ to an oxygen recovery/SO₂ scrubber unit 14 where H₂O and SO₂ are passed to an electrolyzer 16 energized with D.C. electricity 18 to provide H₂ shown as 6 and H₂SO₄, where the latter is vaporized in preheater/vaporizer 20 by thermal energy 22 to feed vaporized H₂SO₄ to the oxygen generator/sulfuric acid decomposition reactor 12, as shown.

As shown in FIG. 2, a Sakuri 2000 process schematic of the reactions for S/I vs. temperature, Sulfuric acid 26 is vaporized in vaporizer 28 and then passed to decomposition reactor 30 at about 760° C. to 810° C. to generate O₂ and pass O₂, H₂O and SO₂ to iodine reactor 32 which generates HI which is decomposed in second decomposition reactor 34 to provide H₂ shown as 6 after passing through the excess 12 separator 36. The decomposition reactor 34 provides the main source of 12, shown as 38 for the iodine reactor 32, also known as a Bunsen reactor.

By operating the entire WSP or S/I cycle at a high pressure of roughly 1450 psi (10.0 MPa-mega pascals), SO₂ can be removed from the system in Unit 14 at temperatures above 20° C. to 75° C., without the use of energetically inefficient refrigeration systems or excess water.

A variety of advances are proposed, that, when taken together, solve most of the issues discussed at the end of the SUMMARY. The first is to use an integrated process that preferably uses a steam based Rankine Cycle for electrical generation. This unusual approach is shown in FIG. 3.

For high temperature heat sources, a Brayton cycle utilizing a gas turbine is more efficient that a Rankine cycle that uses steam as an intermediate fluid between the high temperature hot gas source and the Turbine. However, as the temperature of the hot gas source decreases to about 750° C., the Rankine cycle becomes more efficient than the Brayton cycle. This is the case when using the high temperature heat source to first decompose H₂SO₄. The resulting temperature is about 750° C. and results, surprisingly, in a Rankine cycle effectiveness that is greater than Brayton effectiveness.

Cooling the SO₂/O₂/H₂O mixture to 90° C., in or before Unit 14, from the outlet temperature of the H₂SO₄ reactor 12 amounts to a considerable heat duty, (See Table 1 below):

TABLE 1 Effect of Pressure on Energy Delivered to Power Conversion unit (PCT) and Net WSP Process Efficiency SO_(x) Stream MW(t) Hydrogen Temperature to SO₂ Transferred Production WSP Pressure Scubber Cooler to PCU/Total Rate Process (MPa) (° C.) Available (kg/sec) Efficiency 9 262 59.2/59.2 0.797 42.0% 8 259 61.4/61.4 0.778 42.0% 7 255 63.7/65.2 0.748 41.5% 6 249 60.5/66.4 0.725 40.3% 5 240 56.1/70.5 0.704 38.9% 4 229 50.7/71.2 0.682 37.3%

If the heat from the SO₂/O₂/H₂O mixture is cooled using a water cooled heat exchanger/SO₂ scrubber unit, 14 of FIG. 1, by using the hot SO₂/O₂/H₂O stream to preheat the feed water to the Rankine cycle power conversion unit, as shown in FIG. 3, heat can be beneficially used. However, the amount of heat that can be beneficially used depends upon the inlet temperature of the SO₂/O₂/H₂O stream and on the boiling temperature of the Rankine cycle. The temperatures of these streams in turn depend upon the pressures in the Decomposition Reactor and Rankine cycle boiler. Calculations have indicated that for an 18 MPa Rankine cycle PCU, the percentage of energy that can be beneficially used for feed water preheat is significantly lower than 100% if the pressure in the Decomposition Reactor, 12 in FIG. 1, is below 7 to 9 MPa.

An actual Rankine cycle is accompanied by inefficiencies. The T-S diagram in FIG. 4 shows an actual cycle. The path shown as (1′) to (1) represents the pumping of the working fluid back to the high pressure of the boiler.

The path shown as (1) to (2) represents the preheating of the boiler feedwater carried out by the SO₂/O₂/H₂O stream. The path shown as (2) to (3) represents the boiling of the water by the hot He from the exit of the decomposition reactor. Since a wet vapor will erode the turbine blades, the vapor is usually superheated to condition (4). The expansion may have some inefficiencies and hence not be adiabatic and reversible, so that the expansion step is shown in path (4) to (5) as having a slight increase in entropy. The vapor leaving the turbine may not be saturated so that the omitted portion of the heat exchanger removes sensible heat from the vapor as in step (5) to (5′). More detail can be found in Equilibrium Thermodynamics James Coull and Edward Stuart, John Wiley & Sons, 1964, pages 344-346.

Very importantly, a dual-pressure system is proposed for the inventive process of this invention. The Decomposition Reactor, 12 in FIG. 1, is operated at 7 to 9 MPa, where essentially all of the SO_(x) cooling duty can be recovered as PCU-Rankine Cycle-feed water preheat. To substantially reduce cost in the SO₂ scrubbing-electrolysis processes, Units 14-16 of FIG. 1, the pressure of this portion of the system, Units 14 and 16 in FIG. 1, is reduced below the Decomposition Reactor 12 pressure of 7 to 9 MPa. The low pressure side of the Hybrid Sulfur Process, 14-16 in FIG. 1, however, must still maintain a pressure high enough to absorb the SO₂ produced in the Decomposition Reactor 12 in the feed solution to the electrolyzer. Otherwise, excessive amounts of SO₂ are lost with the O₂ product and create a problem as shown in Table 2 below:

TABLE 2 SO₂ Loss to O₂ Stream as Function of Pressure and Number of Absorption/Electrolysis Single/Three Stage SO2 Losses to O2 Product Single/Three Stage Pressure (MPa) (kg/hr) % SO₂ in O₂ 9  0.46/0.006  6.7%/0.094% 8 0.755/0.020   11%/0.32% 7  1.4/0.111   19%/1.18% 6  2.6/0.472  31%/7.5% 5  5.0/1.57 47%/22% 4 11.0/4.11 66%/43%

To solve this problem, very importantly, a multi-staged SO₂ absorption/electrolysis process is proposed as a preferred embodiment, as shown in FIG. 6. The figure illustrates a system with three parallel, 14′, 14′, 14′/16′, 16′, 16′, SO₂ absorber-absorption/electrolysis stages, although as many stages as are necessary to produce the desired SO₂ in O₂ level can be used-a plurality of preferably parallel stages. In this important approach, SO₂ is absorbed and electrolyzed to H₂SO₄ in several stages. The sulfuric acid leaving each electrolysis stage is therefore depleted in SO₂, allowing the acid to be efficiently used as the scrubbing liquor for the next absorption stage in the cascade. This approach dramatically reduces the SO₂ lost to the O₂, while still operating at a significantly lower pressure than is required in the Decomposition Reactor (see text and Table 1). From a practical point of view, this approach, therefore, substantially lowers the cost of the equipment in the electrolysis area by lowering the pressure, making the entire process more commercially feasible.

Referring now back to FIG. 3, a diagram illustrating a PCU—Hybrid Sulfur System is shown where thermal energy losses are minimized. Nuclear reactor or gas fired combustor 40, shown here as a PBMR, provides fluid heat 42, here He at 950° C. to a first intermediate heat exchanger 44 which passes heat 46 to a hybrid sulfur process such as shown in FIGS. 1 or 2, here a WSP 2 and also passes heat 48 to a Rankine Cycle PCU 50, at about 776° C. Any fluid heat 52, out of the WSP, 2, is passed back to the first intermediate heat exchanger 44. Electrical power 54 from the Rankine Cycle 50 is used to power an electrolyzer, shown in FIG. 1 as Unit 16, in the WSP, 2. The Rankine Cycle passes cooled fluid heat 56 back to PBMR, 40, all as shown in FIG. 3 in complete detail including He temperatures an energy data.

In this invention a hybrid sulfur process such as for example generally shown in FIG. 1, a WSP comprises: (1) a sulfur cycle, preferably a Westinghouse Sulfur Process 2 comprising an electrolyzer 16 which provides H₂SO₄ liquid to a H₂SO₄ preheater/vaporizer/decomposition reactor 20, shown in FIG. 1, operating at a pressure of from 1 MPa to 9 MPa and a temperature effective to provide vaporized gaseous H₂SO₄ which is passed to a sulfuric acid decomposition reactor 12 operating at a temperature over 760° C., utilizing a heat source 10—thermal energy, where decomposed H₂SO₄ comprising H₂O, SO₂ and O₂ is passed preferably to a plurality of SO₂ scrubber units 14′ operated in parallel with a plurality of electrolyzer units 16′, as shown in FIG. 6, where input electricity to the electrolyzer units result in the production of hydrogen gas, where both the SO₂ scrubber units and the electrolyzer units operate at a pressure of 0.1 MPa to 7 MPa, thus providing a dual pressure system; (2) Rankine Cycle Power Conversion Unit 50, which supplies electricity to the sulfur cycle and the plurality of electrolyzer units; and (3) a heat source 40 selected from the group consisting of a nuclear reactor and a gas fired combustor which supply fluid heat to the Rankine Cycle Unit 50 and the sulfur cycle. The heat source is preferably a nuclear reactor.

Referring now to FIG. 5. FIG. 5 generally shows how the heat from the hot SO₂/O₂/H₂O stream is integrated into the operation of the Rankine Cycle, also shown as 50 in FIG. 3. It also shows how the heat from the gas exiting the decomposition reactor is used to heat the feed water, from feedwater pump shown, to steam. Note that FIG. 5 show a two stage Rankine Turbine Cycle with superheat and reheat. Any number of steam turbine stages with appropriate super and preheat stages can be used as is necessary while still being covered by this invention. In FIG. 5, 60 shows cold SO₂/O₂/H₂O which will pass to the multistage SO₂ absorber and 62 shows hot SO₂/O₂/H₂O from the outlet of the decomposition reactor.

A further advance is to use a direct contact heat exchanger and H₂SO₄ concentrator for the decomposition reactor feed system. Traditional heat exchangers would require very large heat exchange areas and result in very expensive and large pieces of equipment. Use of indirect heat exchange is limited by internal temperature pinches i.e. a point in the heat exchanger where the fluid temperature of the high temperature side approaches the temperature of the low temperature side due to phase changes occurring on both sides of the Preheater. Here, the process produces a very concentrated (80% to 95%) H₂SO₄ feed stream for the Decomposition Reactor, shown as 12 in FIG. 1, (significantly reducing the energy duty for evaporating excess water), and efficiently exchanges energy between the Decomposition Reactor products and the feeds. If the H₂SO₄ concentrator/vaporizer/pre-heater, 20 in FIG. 1, is physically located above the Decomposition Reactor, 12 in FIG. 1, as a combination unit, as shown in FIG. 7, the combination eliminates the need for a pump to feed the Decomposition Reactor, since the liquid feed to the reactor is much denser than the products leaving reactor. FIG. 7, in more detail illustrates one potential arrangement of the direct contact concentrator, above in gravity relationship with, decomposition reactors.

In a final design feature, the recycle sulfuric acid is further reduced in pressure with respect to the absorption/electrolysis section to atmospheric pressure. This reduces the cost of the acid storage tank, and allows dissolved O₂ and reduced SO₂ to off-gas from the acid, reducing the corrosivity of the Decomposition Reactor feed and improving the conversion of the H₂SO₄ to SO₂/O₂/H₂O, by removing excess products from the feed.

Having described the presently preferred embodiments, it is to be understood that the invention may be otherwise-embodied within the scope of the appended claims. 

1. A dual pressure hybrid sulfur process for hydrogen generation, utilizing the decomposition of H₂SO₄ to H₂O, SO₂ and O₂ with heat from a nuclear reactor or natural gas fired combustor, which comprises: (a) utilizing a sulfur cycle, selected from the group consisting of a Westinghouse Sulfur Process and a Sulfur Iodine Process, wherein an electrolyzer provides H₂SO₄ liquid to a H₂SO₄ vaporizer reactor operating at a pressure and a temperature effective to provide vaporized gaseous H₂SO₄; which gaseous H₂SO₄ is decomposed to gaseous H₂O, SO₂ and O₂ in a decomposition reactor operating at a pressure of from 7 MPa to 9 MPa; (b) passing the H₂O, SO₂ and O₂ gases to a plurality of SO₂ scrubber units to remove O₂ streams, operating with a plurality of electrolyzer units; (c) inputting electricity to the plurality of electrolyzer units to produce hydrogen gas and H₂SO₄ liquid, where both the plurality of SO₂ scrubber units and the plurality of electrolyzer units operate at a pressure of 0.1 MPa to 7 MPa; (d) supplying electricity to the plurality of electrolyzer units utilizing a Rankine Cycle Power Conversion Unit; and (e) supplying fluid heat to the Rankine Cycle Unit and the sulfur cycle, utilizing a heat source selected from the group consisting of a nuclear reactor and a natural gas fired combustor; where the decomposition reactor operates at a pressure higher than the scrubber and electrolyzer units, providing a dual pressure hybrid process.
 2. The hybrid sulfur process of claim 1, wherein a combination heat exchanger and H₂SO₄ vaporizer are used to preheat the inlet liquid sulfuric liquid and concentrate it to between 80% and 95% H₂SO₄, and feed the hot concentrated H₂SO₄ to the decomposition reactor.
 3. The hybrid sulfur process of claim 2, wherein the H₂SO₄ vaporizer reactor is located above the decomposition reactor, allowing gravity flow of concentrated/gaseous H₂SO₄ to eliminate the need for a pump to supply the decomposition reactor.
 4. The hybrid sulfur process of claim 1, wherein the plurality of SO₂ scrubber units and electrolyzer units reduces SO₂ loss to the O₂ streams.
 5. The hybrid sulfur process of claim 4, wherein SO₂ is absorbed and electrolyzed to H₂SO₄ in several stages, so that the sulfuric acid leaving each electrolyzer unit is depleted in SO₂ allowing acid to be efficiently used in the scrubbing liquid for the next absorption stage.
 6. The hybrid sulfur process of claim 1, wherein the Rankine Cycle is steam based and passes cooled fluid heat back to the heat source.
 7. The hybrid sulfur process of claim 1, wherein the decomposition reactor is operated at about 750° C.-760° C., to increase the efficiency of the associated Rankine Cycle.
 8. The hybrid sulfur process of claim 1, wherein the heat source is a nuclear reactor and the sulfur cycle is a Westinghouse Sulfur Process.
 9. The hybrid sulfur process of claim 8, wherein fluid heat from the nuclear reactor is first passed to a heat exchanger then to the Rankine cycle. 